COMMUNICATION pubs.acs.org/IC
Solid-State Dinuclear-to-Trinuclear Conversion in an Oxalato-Bridged Chromium(III)-Cobalt(II) Complex as a New Route toward Single-Molecule Magnets Julia Vallejo,† Isabel Castro,*,† Jesus Ferrando-Soria,† Maria del Pino Deniz-Hernandez,‡ Catalina Ruiz-Perez,‡ Francesc Lloret,† Miguel Julve,† Rafael Ruiz-García,†,§ and Joan Cano*,†,§ †
Departament de Química Inorganica/Instituto de Ciencia Molecular (ICMol) and Fundaci o General de la Universitat de Valencia (FGUV), Universitat de Valencia, E-46980 Paterna, Valencia, Spain ‡ Laboratorio de Rayos X y Materiales Moleculares, Departamento de Física Fundamental II, Facultad de Física, Universidad de La Laguna, E-38071 La Laguna, Tenerife, Spain §
bS Supporting Information Chart 1 ABSTRACT: A novel bis(oxalato)chromium(III) salt of a ferromagnetically coupled, oxalato-bridged dinuclear chromium(III)-cobalt(II) complex of formula [CrL(ox)2CoL0 (H2O)2][CrL(ox)2] 3 4H2O (1) has been self-assembled in solution using different aromatic R,R0 -diimines as blocking ligands, such as 2,20 -bipyridine (L = bpy) and 2,9dimethyl-1,10-phenanthroline (L0 = Me2phen). Thermal dehydration of 1 leads to an intriguing solid-state reaction between the S = 3/2 CrIII anions and the S = 3 CrIIICoII cations to give a ferromagnetically coupled, oxalato-bridged trinuclear chromium(III)-cobalt(II) complex of formula {[CrL(ox)2]2CoL0 } (2). Complex 2 possesses a moderately anisotropic S = 9/2 CrIII2CoII ground state, and it exhibits slow magnetic relaxation behavior at very low temperatures (TB < 2.0 K).
olynuclear complexes of paramagnetic first-row transitionmetal ions have been the subject of a renewed interest in the last years as potential candidates of single-molecule magnets (SMMs) or as precursors of single-chain magnets (SCMs), i.e., molecules with either discrete zero-dimensional (0D) or extended one-dimensional (1D) structures that exhibit slow relaxation of the magnetization below a blocking temperature (TB).1,2 Otherwise, the use of small polynuclear complexes as precursors of two- (2D) or three-dimensional (3D) magnets possessing a long-range magnetic ordering below a critical temperature (TC) was a worthwhile topic in the past.3 In all cases, however, the polymerization reactions leading to the nD (n = 1-3) polymetallic magnetic systems, either in solution2 or in the solid state,3 are difficult to control. The “complex-as-ligand/complex-as-metal” approach represents a rational method toward the preparation of discrete heteropolynuclear species with predetermined structures and spin topologies.4 In this context, we recently showed that neutral trinuclear chromium(III)-cobalt(II) complexes, {[CrIIIL(ox)2]2 CoIIL0 }, can be rationally designed and synthesized from anionic mononuclear bis(oxalato)chromium(III) complexes, [CrIIIL(ox)2]-, acting as bidentate ligands (metalloligands) toward
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coordinatively unsaturated cationic cobalt(II) complexes, [CoIIL0 (H2O)4]2þ, where L and L0 are aromatic R,R0 -diimine blocking ligands like 2,20 -bipyridine (L = bpy) or 1,10-phenanthroline (L = phen) and their β,β0 -dimethyl-substituted derivative 6,60 dimethyl-2,20 -bipyridine (L0 = Me2bpy) (Chart 1).5 Surprisingly, when using the 2,9-dimethyl-1,10-phenanthroline (L0 = Me2phen) analogue as a blocking ligand, the cationic dinuclear chromium(III)-cobalt(II) complexes [CrIIIL(ox)2CoIIL0 ]þ were isolated as their anionic mononuclear chromium(III) salts. Herein we report the synthesis, crystal structure, thermal behavior, and magnetic properties of such a new complex of formula [Cr(bpy)(ox)2Co(Me2phen)(H2O)2][Cr(bpy)(ox)2] 3 4H2O (1). Interestingly, 1 exhibits an intriguing solvatomagnetic behavior upon thermal dehydration, which reveals the occurrence of a solidstate reaction to give the corresponding trinuclear chromium(III)cobalt(II) anhydrous derivative of formula {[Cr(bpy)(ox)2]2Co(Me2phen)} (2). The crystal structure of 1 consists of oxalato-bridged heterodinuclear chromium(III)-cobalt(II) cations, [CrIII(bpy)(ox)2CoII (Me2phen)(H2O)2]þ, mononuclear bis(oxalato)chromium(III) Received: December 17, 2010 Published: February 01, 2011 2073
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Inorganic Chemistry
Figure 1. (a) Perspective view of the asymmetric unit of 1 with the atom-numbering scheme for the metal coordination environments and crystallization water molecules. Hydrogen bonds are represented by dashed lines (hydrogen atoms are omitted for clarity). Selected intermetallic distances (Å) with standard deviations in parentheses: Cr(1)-Co(1) =5.423(2), Cr(2)-Co(1) =7.879(2), and Cr(1)-Cr(2) =7.306(4).
anions, [CrIII(bpy)(ox)2]-, and crystallization water molecules (Figure 1). One of the two [CrIII(bpy)(ox)2]- anionic units of 1 coordinates to the trans-diaqua [CoII(Me2phen)(H2O)2]2þ moiety in a bidentate manner through one of the two oxalato groups. The other [CrIII(bpy)(ox)2]- anionic unit establishes a variety of hydrogen bonds with the resulting [CrIII(bpy)(ox)2 CoII(Me2phen)(H2O)2]þ cationic entity which involve the free carbonyl-oxygen atoms from a terminally bound oxalato group and the coordinated and crystallization water molecules [O 3 3 3 Ow = 2.761(1)-2.876(1) Å]. This situation contrasts with that found in the related oxalato-bridged heterotrinuclear cobalt(II)-chromium(III) complex of formula {[Cr(phen) (ox)2 ]2 Co(Me2 bpy)2 } 3 1.5H2 O, whereby the two [Cr III(phen)(ox)2]- units coordinate to the [CoII(Me2bpy)2]2þ unit in a bidentate manner.5 The greater steric hindrance of the Me2phen blocking ligand compared to the Me2bpy one would account for this structural difference. The Cr(1) and Cr(2) atoms of 1 adopt a similar trigonally distorted octahedral geometry [Cr-N = 2.054(3)-2.067(3) Å and Cr-O = 1.938(3)-2.005(3) Å], while the Co(1) atom exhibits an axially compressed octahedral geometry typical of a high-spin CoII ion [Co-N = 2.149(3)-2.151(3) Å, Co-O = 2.152(3)-2.179(2) Å, and Co-Ow = 2.029(3)-2.088(3) Å]. The thermogravimetrogram of 1 under a dry N2 atmosphere shows a fast weight loss from room temperature to around 165 °C, which is followed by a plateau under further heating to 300 °C just when decomposition occurs (Figure S1, Supporting Information). The value of the mass loss percentage of ca. 10% corresponds to six water molecules per formula unit. This agrees with the release of both the
COMMUNICATION
Figure 2. (a) χMT vs T plot for 1 (O) and 2 (0) under dc fields of 10 kOe (T g 25 K) and 250 Oe (T < 25 K). The solid lines are the best-fit curves (see the text). The inset shows the M vs H plots for 1 (b) and 2 (9) at T = 2.0 K. The solid, dashed, and dotted lines are the Brillouin curves for one S = 9/2, one SCr = 3/2 plus one S = 3, and two SCr = 3/2 plus one SCo = 3/2 states, respectively (see the text). (b) χM0 (open symbols) and χM00 (closed symbols) vs T plots for 2 at different frequencies of the 4.0 Oe ac field: 10 (O, b), 100 (0, 9), 333 (), (), 1000 (Δ, 2), and 1400 Hz (3, 1). The solid lines are guides for the eye.
crystallization and coordinated water molecules to give the anhydrous derivative 2. The direct-current (dc) magnetic properties of 1 and 2 in the form of χT vs T plots (with χM being the molar magnetic susceptibility and T the temperature) show a dramatically different magnetic behavior, which is consistent with their mononuclear plus dinuclear (1) and trinuclear (2) structures (Figure 2a). At room temperature, the values of χMT are 5.82 (1) and 5.80 cm3 mol-1 K (2). They are close to that expected for the sum of two d3 CrIII (SCr = 3/2) ions and one high-spin d7 CoII (SCo = 3/2) ion magnetically isolated [χMT = 2(Nβ2gCr2/ 3kB)SCr(SCr þ 1) þ (Nβ2gM2/3kB)SCo(SCo þ 1) = 5.8 cm3 mol-1 K with gCr = 2.0 and gCo = 2.1]. Upon cooling, χMT for 1 slightly increases to reach a maximum of 6.14 cm3 mol-1 K at 14 K, and then it abruptly decreases to 5.05 cm3 mol-1 K at 2.0 K. Instead, χMT for 2 increases abruptly below 50 K to reach a maximum of 8.43 cm3 mol-1 K at 3.5 K, and then it slightly decreases to 7.81 cm3 mol-1 K at 2.0 K. The increase of χMT at high temperatures for 1 and 2 agrees with the occurrence of a moderately weak ferromagnetic intramolecular interaction between the CrIII (SCr = 3/2) and the high-spin CoII (SCo = 3/2) ions through the oxalato bridge within the CrIIICoII (1) and CrIII2CoII (2) units. The maximum χMT values for 1 and 2 are yet below those expected for magnetically isolated SCr=3/2 CrIII and S = 3 CrIIICoII units in 1 [χMT = (Nβ2gCr2/3k)SCr(SCr þ 1) þ (Nβ2g2/3k)S(S þ 1) = 8.2 cm3 mol-1 K with gCr = 2.0 and 2074
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g = (gCr þ gCo)/2 = 2.05] or S = 9/2 CrIII2CoII units in 2 [χMT = (Nβ2g2/3k)S(S þ 1) = 12.8 cm3 mol-1 K with g = (2gCr þ gCo)/ 3 = 2.033]. The decrease of χMT at low temperatures for 1 and 2 is most likely due to antiferromagnetic intermolecular interactions and/or zero-field-splitting (ZFS) effects. In fact, the M vs H plots (with M being the molar magnetization and H the dc field) of 1 and 2 at 2.0 K agree with a solid-state reaction between the SCr = 3/2 CrIII and S = 3 CrIIICoII units to give a S = 9/2 CrIII2CoII entity (inset of Figure 2a). Thus, the isothermal magnetization curve at low H values for 1 is intermediate between the Brillouin functions of three quartet states (SCr = SCo = 3/2 with gCr = 2.0 and gCo = 2.1, respectively) and one quartet (SCr = 3/2 with gCr = 2.0) plus one septet (S = 3/2 with g = 2.05) states (dotted and dashed lines respectively, in the inset of Figure 2a), while that of 2 is fairly close to the Brillouin function of a decet (S = 9/2 with g = 2.033) state (solid line in the inset of Figure 2a). Yet, the M values of 8.18 (1) and 8.32 μB (2) at 50 kOe are slightly below the saturation magnetization for the sum of two CrIII (SCr = 3/2) and one high-spin CoII (SCr = 3/2) ions (Ms = 2gCrSCr þ gCoSCo = 9.15 μB with gCr = 2.0 and gCo = 2.1), supporting thus the presence of a significant single-ion axial magnetic anisotropy of the high-spin CoII ion in a distorted octahedral coordination geometry. The magnetic susceptibility data of 1 and 2 were analyzed through the appropriate spin Hamiltonian for mononuclear plus dinuclear (1) and trinuclear (2) models by taking into account both the presence of weak intermolecular interactions within the mean-field approximation and the local axial ZFS of the orbital singlet 4Eg ground state of the high-spin CoII ion in an axially compressed octahedral geometry (D4h point group) [eqs 1 and 2, with SCr1 = SCr2 = SCo1 = 3/2],5 where J and zj are the intra- and intermolecular magnetic coupling parameters, respectively, D is the axial magnetic anisotropy parameter of the CoII ion, and gCr and gCo are the Lande factors of the CrIII and CoII ions. The leastsquares fits of the experimental data by full-matrix diagonalization techniques gave J = þ2.16 cm-1, zj = -0.15 cm-1, D = -0.61 cm-1, gCo = 2.082, and gCr = 2.002 for 1 and J = þ1.81 cm-1, zj = -0.09 cm-1, D = -1.27 cm-1, gCo = 2.092, and gCr = 1.998 for 2. The theoretical curves closely match the experimental data for 1 and 2 (solid lines in Figure 2a). In particular, they reproduce very well the maximum of χMT at low temperatures. The calculated values of J and D for 1 and 2 are close to those previously found in {[Cr(phen)(ox)2]2Co(Me2bpy)2} 3 1.5H2O (J = þ2.34 cm-1 and D = -2.15 cm-1).5 H ¼ -JSCr1 3 SCo1 þ zjhSz iSz þ DSCo1z 2 þ gCr ðSCr1 þ SCr2 ÞμB H þgCo SCo1 μB H
ð1Þ
H ¼ -JðSCr1 3 SCo1 þSCr2 3 SCo1 Þ þ zjhSz iSz þDSCo1z 2 þ gCr ðSCr1 þ SCr2 ÞμB H þ gCo SCo1 μB H
ð2Þ
Finally, the alternating-current (ac) magnetic properties of 2 in the form of the χM0 and χM00 vs T plots (with χM0 and χM00 being the in-phase and out-of-phase ac molar magnetic susceptibilities) show evidence of incipient spin-blocking effects, which are characteristic of SMMs (Figure 2b). As the frequency of the ac field increases in the range 10-1400 Hz, χM0 decreases slightly while χM00 becomes different from zero below 3.0 K. However, no maxima of χM00 were observed above 2.0 K, even for the highest frequency used (ν = 1400 Hz), indicating thus that TB < 2.0 K for this new example of an oxalato-bridged SMM.6,7 The
preexponential factor (τ0) and energy barrier (U) to reverse the magnetization can be roughly estimated from the χM00 /χM0 vs 1/T plots at a given frequency of the ac field by considering a single relaxation time (Figure S2, Supporting Information).8 The least-squares fits of the experimental data through the expression χM00 /χM0 = 2πντ0 exp(U/kBT) gave τ0 ≈ 2 10-9 s and U ≈ 13 cm-1 for 2 (solid lines in Figure S2, Supporting Information). In summary, we have developed a combined solution and solid-state synthetic procedure for the stepwise self-assembly of moderately anisotropic ferromagnetically coupled, oxalatobridged heteropolynuclear chromium(III)-cobalt(II) complexes, as potential candidates to SMMs. The formation of discrete polynuclear complexes following dehydration reactions in the solid state is rare; more frequently, extended polymers are formed upon vacuum or thermal dehydration in the absence of blocking ligands. The formation of a discrete S = 9/2 CrIII2CoII complex upon dehydration of 1 to give 2 is then favored because of the presence of the aromatic R,R0 -diimines as blocking ligands. Current efforts are devoted to investigating the magnetic relaxation dynamics of this moderately anisotropic high-spin molecule at very low temperatures.
’ ASSOCIATED CONTENT
bS
Supporting Information. Preparation and characterization of 1 and 2, X-ray crystallographic data of 1 in CIF format, thermogravimetrogram of 1 (Figure S1), and χM00 /χM0 vs 1/T plots of 2 (Figure S2). This material is available free of charge via the Internet at http://pubs.acs.org.
’ AUTHOR INFORMATION Corresponding Author
*E-mail:
[email protected] (I.C.),
[email protected] (J.C.).
’ ACKNOWLEDGMENT This work was supported by the MICINN, Spain (Projects CTQ2010-15364, MAT2007-60660, CSD2007-00010, and CSD2006-00015), the Generalitat Valenciana, Spain (Projects GVPRE/2008 and PROMETEO/2009/108), and the Gobierno Autonomo de Canarias, Spain (Project PI2002/175). J.F.-S. thanks the Generalitat Valenciana for a doctoral grant. ’ REFERENCES (1) Aromi, G.; Brechin, E. K. Struct. Bonding (Berlin) 2006, 122, 1. (2) Miyasaka, H.; Julve, M.; Yamashita, M.; Clerac, R. Inorg. Chem. 2009, 48, 3420. (3) Kahn, O.; Pei, Y.; Nakatani, K.; Journaux, Y. New J. Chem. 1992, 16, 269. (4) Marinescu, G.; Andruh, M.; Lloret, F.; Julve, M. Coord. Chem. Rev. 2011, 255, 161. (5) Vallejo, J.; Castro, I.; Ca~ nadillas-Delgado, L.; Ruiz-Perez, C.; Ferrando-Soria, J.; Ruiz-García, R.; Cano, J.; Lloret, F.; Julve, M. Dalton Trans. 2010, 39, 2350. (6) Martínez-Lillo, J.; Armentano, D.; De Munno, G.; Wernsdorfer, W.; Julve, M.; Lloret, F.; Faus, J. J. Am. Chem. Soc. 2006, 128, 14218. (7) Xu, G.-F.; Wang, Q.-L.; Gamez, P.; Ma, Y.; Clerac, R.; Tang, J.; Yan, S.-P.; Cheng, P.; Liao, D.-Z. Chem. Commun. 2010, 46, 1506. (8) Bartolome, J.; Filoti, G.; Kuncser, V.; Schinteie, G.; Mereacre, V.; Anson, C. E.; Powell, A. K.; Prodius, D.; Turta, C. Phys. Rev. B 2009, 80, 014430. 2075
dx.doi.org/10.1021/ic1025203 |Inorg. Chem. 2011, 50, 2073–2075